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All Journal International Journal of Power Electronics and Drive Systems (IJPEDS)
Yadlapti Suresh
Prasad V Potluri Siddhartha Institute of Technology
Control & Systems Engineering Electrical & Electronics Engineering

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An enhanced hybrid deep learning-quantum variational classifier framework for large-scale data analytics Yadlapti Suresh; Venu Gopal Gaddam; Challa Naga Venkata Jyothirmai; Rokkam Veera Venkata Nagendra Bheema Rao; Sreenivasulu Bolla; Ankala Radhika
International Journal of Power Electronics and Drive Systems (IJPEDS) Vol 17, No 2: June 2026
Publisher : Institute of Advanced Engineering and Science

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.11591/ijpeds.v17.i2.pp1522-1532

Abstract

The rapid expansion of clinical data in modern healthcare requires analytical systems capable of uncovering intricate patterns and supporting accurate diagnostic decisions. Quantum machine learning (QML) offers significant potential for modeling higher-order feature interactions and accelerating computation beyond classical approaches. This paper introduces an improved hybrid architecture that fuses an inception-based attentional VGG (IAV) network with a quantum variational classifier (QVC) constructed using parameterized quantum circuits (PQCs). The framework begins with min-max normalization to stabilize heterogeneous clinical attributes and enhance training convergence. Deep discriminative features are then extracted through the IAV model, followed by quantum-driven classification using variational layers optimized by classical routines. The MIMIC-III clinical dataset is employed to validate the proposed system on large-scale healthcare records. Performance is measured using accuracy, precision, recall, and F1-score. The enhanced hybrid model achieves 97.28% accuracy, 97.16% precision, 96.65% recall, and a 97.38% F1-score, surpassing established methods including support vector machine (SVM) (89.23%), quantum support vector machine (QSVM) (90.13%), and QVKSVM (97.34%). The findings confirm that integrating deep learning with quantum variational optimization strengthens scalability, reduces computational overhead, and establishes a powerful foundation for next-generation healthcare analytics.
Co-Authors Ankala Radhika Challa Naga Venkata Jyothirmai Rokkam Veera Venkata Nagendra Bheema Rao Sreenivasulu Bolla Venu Gopal Gaddam